A Brayton cycle engine and method for operation. The engine includes an inner wall assembly and an upstream wall assembly each extended from a longitudinal wall into a gas flowpath. An actuator adjusts a depth of the detonation combustion region into the gas flowpath between the inner wall assembly and the upstream wall assembly. The engine flows an oxidizer through the gas flowpath and the inner wall captures a portion of the oxidizer. The engine further adjusts the captured flow of oxidizer via the upstream wall and flows a first flow of fuel to the captured flow of oxidizer to produce rotating detonation gases. The engine flows the detonation gases downstream and to mix with the flow of oxidizer, and flows and burns a second flow of fuel to the detonation gases/oxidizer mixture to produce thrust.
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1. A method for operating an engine, the engine comprising (a) a longitudinal wall extended along a lengthwise direction, wherein the longitudinal wall defines a gas flowpath of the engine and a combustion section, the gas flowpath having a depth perpendicular to the longitudinal wall, (b) an inner wall assembly extendable from the longitudinal wall into the gas flowpath, wherein the inner wall assembly includes a concave upstream face that defines a rotating detonation combustion region at an upstream side of the inner wall assembly and adjacent to the longitudinal wall, and (c) an upstream wall assembly coupled to the longitudinal wall upstream of the inner wall assembly, wherein an actuator is coupled to the upstream wall assembly and is configured to actuate the upstream wall assembly to extend the upstream wall assembly into the gas flowpath a depth, the method comprising:
flowing an oxidizer through the gas flowpath into the combustion section, wherein the flow of oxidizer includes a first portion and a second portion;
capturing the first portion of the flow of oxidizer at the rotating detonation combustion region via the concave upstream face of the inner wall assembly being extended into the gas flowpath a depth;
adjusting an amount of the first portion of the flow of oxidizer provided to the concave upstream face of the inner wall assembly via actuating the upstream wall assembly to adjust the depth of the upstream wall assembly extended into the gas flowpath;
flowing a first flow of fuel to the first portion of the flow of oxidizer at the rotating detonation combustion region;
producing a rotating detonation wave of detonation gases at the rotating detonation combustion region via a first mixture of the first flow of fuel and the first portion of the flow of oxidizer;
adjusting a size of the rotation detonation wave at the rotating detonation combustion region by adjusting a depth of the inner wall assembly extended into the gas flowpath;
mixing at least a portion of the detonation gases from the rotating detonation combustion region with a second flow of fuel and the second portion of the flow of oxidizer in the gas flowpath; and
burning a second mixture including the second flow of fuel, at least the portion of the detonation gases, and the second portion of the flow of oxidizer, wherein burning the second mixture is downstream of the rotating detonation wave of detonation gases relative to the gas flowpath.
2. The method of
3. The method of
4. The method of
5. The method of
adjusting a cross sectional area of the gas flowpath based on an operating condition of the engine.
6. The method of
adjusting the depth the upstream wall assembly extended into the gas flowpath based at least on the operating condition of the engine.
7. The method of
8. The method of
9. The method of
adjusting a profile of the oblique shockwave based on an operating condition of the engine.
10. The method of
adjusting the depth of the upstream wall extended into the gas flowpath.
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The present subject matter is related to continuous detonation combustion systems for Brayton cycle machines.
Propulsion systems, including gas turbines, ramjets, and scramjets, often use deflagrative combustion systems to burn a fuel/oxidizer mixture to produce combustion gases that are expanded and released to produce thrust. While such propulsion systems have reached a high level of thermodynamic efficiency through steady improvements in component efficiencies and increases in pressure ratio and peak temperatures, further improvements are nonetheless welcome in the art.
More particularly, further improvements are desired in stabilization of the combustion process generally. More specifically, further improvements are desired for combustion systems applied in gas turbine augmentor/afterburner or inter-turbine burner systems, ramjets, and scramjets.
Aspects and advantages of the invention will be set forth in part in the following description, or may be obvious from the description, or may be learned through practice of the invention.
The present disclosure is directed to a Brayton cycle engine and method for operation. The engine includes a longitudinal wall extended along a lengthwise direction defining a gas flowpath of the engine. An inner wall assembly is extended from the longitudinal wall into the gas flowpath. The inner wall assembly defines a detonation combustion region in the gas flowpath upstream of the inner wall assembly. An upstream wall assembly is coupled to the longitudinal wall upstream of the inner wall assembly. Various embodiments include an actuator configured to adjust a cross sectional area of the gas flowpath. The actuator adjusts a depth of the detonation combustion region into the gas flowpath. In one embodiment, the actuator is coupled to the upstream wall assembly and the actuator adjusts the depth of the upstream wall assembly in the gas flowpath. The method for operating the engine includes flowing an oxidizer through a gas flowpath into a combustion section; capturing a portion of the flow of oxidizer via an inner wall extended into a depth of the gas flowpath; adjusting the flow of oxidizer to the inner wall via an upstream wall disposed upstream of the inner wall; flowing a first flow of fuel to the portion of the flow of oxidizer captured via the wall; producing a rotating detonation wave of detonation gases via a mixture of the first flow of fuel and the portion of oxidizer upstream of the inner wall; flowing at least a portion of the detonation gases downstream and mixing the detonation gases with the flow of oxidizer; flowing a second flow of fuel to the mixture of detonation gases and the flow of oxidizer; and burning the mixture of the second flow of fuel, the detonation gases, and the flow of oxidizer to produce thrust.
In various embodiments, adjusting the flow of oxidizer to the inner wall is based at least on an operating condition of the engine. In one embodiment, the operating condition of the engine is based at least on a pressure, temperature, or flow rate of the flow of oxidizer at the combustion section.
In one embodiment, adjusting the flow of oxidizer is based at least on a desired minimum number of detonation cells to produce the rotating detonation wave.
In various embodiments, adjusting the flow of oxidizer further includes adjusting a cross sectional area of the gas flowpath based on an operating condition of the engine. In one embodiment, adjusting the cross sectional area of the gas flowpath includes adjusting a depth into the gas flowpath of the upstream wall based at least on an operating condition of the engine.
In one embodiment, burning the mixture of the second flow of fuel, the detonation gases, and the flow of oxidizer to produce thrust comprises a deflagrative combustion process.
In various embodiments, the flow of oxidizer at the combustion section defines a supersonic axial velocity through the gas flowpath producing an oblique shockwave from the flow of oxidizer in the gas flowpath. In one embodiment, the method for operating the engine further includes adjusting a profile of the oblique shockwave based on an operating condition of the engine. In one embodiment, adjusting the profile of the oblique shockwave includes adjusting a depth into the gas flowpath of the upstream wall.
In one embodiment, the detonation combustion region is defined along the lengthwise direction between the upstream wall assembly and the inner wall assembly.
In another embodiment, the engine defines a supersonic combustion ramjet engine.
In various embodiments, the inner wall assembly includes an upstream face extended from the longitudinal wall into the gas flowpath, and a downstream face extended from the longitudinal wall and coupled to the upstream face in the gas flowpath. The downstream face is disposed at an angle relative to the longitudinal wall. In one embodiment, the actuator adjusts the angle of the downstream face relative to the longitudinal wall. In another embodiment, the downstream face of the inner wall assembly defines the second fuel injection port providing a second flow of fuel downstream of the detonation combustion region. In still another embodiment, the upstream face of the inner wall assembly defines the first fuel injection port providing a first flow of fuel to the detonation combustion region.
In various embodiments, the longitudinal wall defines the first fuel injection port providing a first flow of fuel to the detonation combustion region.
These and other features, aspects and advantages of the present invention will become better understood with reference to the following description and appended claims. The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
A full and enabling disclosure of the present invention, including the best mode thereof, directed to one of ordinary skill in the art, is set forth in the specification, which makes reference to the appended figures, in which:
Repeat use of reference characters in the present specification and drawings is intended to represent the same or analogous features or elements of the present invention.
Reference now will be made in detail to embodiments of the invention, one or more examples of which are illustrated in the drawings. Each example is provided by way of explanation of the invention, not limitation of the invention. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope or spirit of the invention. For instance, features illustrated or described as part of one embodiment can be used with another embodiment to yield a still further embodiment. Thus, it is intended that the present invention covers such modifications and variations as come within the scope of the appended claims and their equivalents.
As used herein, the terms “first”, “second”, and “third” may be used interchangeably to distinguish one component from another and are not intended to signify location or importance of the individual components.
The terms “forward” and “aft” refer to relative positions within a heat engine or vehicle, and refer to the normal operational attitude of the heat engine or vehicle. For example, with regard to a heat engine, forward refers to a position closer to a heat engine inlet and aft refers to a position closer to a heat engine nozzle or exhaust.
The terms “upstream” and “downstream” refer to the relative direction with respect to fluid flow in a fluid pathway. For example, “upstream” refers to the direction from which the fluid flows, and “downstream” refers to the direction to which the fluid flows.
The singular forms “a”, “an”, and “the” include plural references unless the context clearly dictates otherwise.
Approximating language, as used herein throughout the specification and claims, is applied to modify any quantitative representation that could permissibly vary without resulting in a change in the basic function to which it is related. Accordingly, a value modified by a term or terms, such as “about”, “approximately”, and “substantially”, are not to be limited to the precise value specified. In at least some instances, the approximating language may correspond to the precision of an instrument for measuring the value, or the precision of the methods or machines for constructing or manufacturing the components and/or systems. For example, the approximating language may refer to being within a 10 percent margin.
Here and throughout the specification and claims, range limitations are combined and interchanged. Such ranges are identified and include all the sub-ranges contained therein unless context or language indicates otherwise. For example, all ranges disclosed herein are inclusive of the endpoints, and the endpoints are independently combinable with each other.
Embodiments of an engine and combustion section are generally provided that improve combustion stability and performance for ramjet and scramjet engines, and gas turbine engines including inter-turbine burners or afterburning exhaust systems, or duct burners generally. Various embodiments of the engine generally provided herein define a rotating detonation combustion region upstream of a main combustion process, such as a conventional or deflagrative combustion process. In various embodiments, the rotating detonation combustion region may generally act as a pilot burner for the downstream conventional combustion process, such as to improve stability and performance of the combustion section of the engine. Furthermore, embodiments of the engine generally provided may effectuate a cross sectional area change of a gas flowpath via modulation of a fuel split between the rotating detonation combustion region and the conventional combustion process, thereby enabling operation of the combustion section over a range or plurality of dynamic pressures in the gas flowpath in contrast to an approximately constant q-path.
Referring now to the drawings,
Referring to
For example, referring to
Referring still to
In the embodiments generally provided in
In other embodiments, such as generally provided in
Referring now to
Referring still to
The inner wall assembly 120 such as described herein may improve stabilization of the downstream combustion process including the oxidizer 81(b) and the second flow of fuel 79 by controlling the production of detonation gases 126 via controlling a flow rate of the first flow of fuel 78 provided to the detonation process within the region 125. For example, the first flow of fuel 78 and the portion of oxidizer 81(a) may together alter a fuel/oxidizer mixture downstream of the inner wall assembly 120. As another example, the inner wall assembly 120 capturing the portion of oxidizer 81(a) and providing the first flow of fuel 78 may define a pilot burner control for the combustion section 100 such as to improve overall combustion stability, performance, or operability at various flow rates, pressures, or temperatures of the flow of oxidizer 81. As still another example, the inner wall assembly 120 generally enables an independent aerodynamic method to provide an area change along the gas flowpath 90 via changes in the first flow of fuel 78, as well as changes in the first flow of fuel 78 relative to the second flow of fuel 79. As such, the inner wall assembly 120 enables operation of the engine 10 over a plurality of dynamic pressures of the flow of oxidizer 81 rather than being restricted to an approximately constant volumetric flow rate through the gas flowpath 90.
Referring back to
Referring back to the generally axisymmetric configurations of the engine 10 generally provided in regard to
The inner wall assembly 120 extended from the first longitudinal wall 111 may define a first rotating detonation combustion region 125(a). The inner wall assembly 120 extended from the second longitudinal wall 112 may define a second rotating detonation combustion region 125(b). As generally depicted in
In one embodiment, the first detonation wave 127(a) and the second detonation wave 127(b) propagate co-rotationally, i.e., the first detonation wave 127(a) and the second detonation wave 127(b) propagate along the same circumferential direction C around the axial centerline 12. In another embodiment, the first detonation wave 127(a) and the second detonation wave 127(b) propagate counter-rotationally, i.e., the first detonation wave 127(a) and the second detonation wave 127(b) propagate along the circumferential direction C around the axial centerline 12 opposite of one another. In various embodiments, the detonation wave 127 may propagate clockwise or counter-clockwise through the gas flowpath 90.
It should be appreciated that descriptions and depictions of detonation wave 127 herein and throughout generally apply to the first detonation wave 127(a) and the second detonation wave 127(b), unless otherwise specified. Still further, it should be appreciated that descriptions and depictions of longitudinal wall 110 herein and throughout generally apply to the first longitudinal wall 111 and the second longitudinal wall 112, unless otherwise specified. Furthermore, it should be appreciated that descriptions and depictions of the region 125 herein and throughout generally apply to the first region 125(a) and the second region 125(b), unless otherwise specified.
Referring now to
In one embodiment of the engine 10, the first fuel injection port 124 is defined through the longitudinal wall 110. For example, the first fuel injection port 124 may be defined through the longitudinal wall 110 upstream of the inner wall assembly 120 such as to provide the first flow of fuel 78 approximately perpendicular to the flow of oxidizer 81 through the gas flowpath 90 into the region 125. As another example, the first fuel injection port is defined generally adjacent to the region 125, such as upstream and adjacent to the upstream face 121 of the inner wall assembly 120.
In another embodiment of the engine 10, the first fuel injection port 124 is defined through the upstream face 121 of the inner wall assembly 120. For example, the first fuel injection port 124 may be defined through the upstream face 121 such as to provide the first flow of fuel 78 into the region 125 approximately parallel to the flow of oxidizer 81 through the gas flowpath 90. In various embodiments, the upstream face 121 is disposed at an angle relative to the direction of flow of oxidizer 81 through the gas flowpath 90. As such, the first fuel injection port 124 may further be defined at an acute angle relative to the direction of flow of oxidizer 81 through the gas flowpath 90, such as generally corresponding to the acute angle of the upstream face 121.
Referring to the exemplary embodiment providing in
Referring to the exemplary embodiment generally provided in
Referring now to the embodiments generally provided in
Still further, the first flow of fuel 78 may be modulated based on a desired location into which the fuel 78 enters the region 125. For example, in one embodiment, the first fuel injection port 124 may be defined through the upstream face 121 and the longitudinal wall 110. As such, fuel 78 may be modulated through the upstream face 121 and the longitudinal wall 110 such as to define different fuel splits or flow rates through each of the upstream face 121 or longitudinal wall 110.
Referring still to
In regard to two-dimensional embodiments of the engine 10, such as generally provided in
In various embodiments, the upstream face 121 is extended from the longitudinal wall 110 into the gas flowpath 90 equal to or less than approximately 20% of depth D. In still yet various embodiments, the upstream face 121 is extended from the longitudinal wall 110 into the gas flowpath 90 equal to or less than approximately 13% of depth D. In still another embodiment, the upstream face 121 is extended from the longitudinal wall 110 into the gas flowpath 90 equal to or less than approximately 7% of depth D.
Referring still to the exemplary embodiments generally provided in
Referring now to
In various embodiments, the engine 10 further includes an actuator 150 coupled to the inner wall assembly 120 to adjust the depth D of the inner wall assembly 120 in the gas flowpath 90. The actuator 150 may extend the inner wall assembly 120, or more specifically, the upstream face 121, to approximately 35% of the depth D of the gas flowpath 90 from the longitudinal wall 110. The actuator 150 may further contract the inner wall assembly 120, or more specifically, the upstream face 121, to approximately 0% of the depth D of the gas flowpath 90. As such, the actuator 150 may contract the inner wall assembly 120 to be approximately flush to the longitudinal wall 110.
Furthermore, actuation or articulation of the inner wall assembly 120 may further be based on a desired angle 128 of the inner wall assembly 120, or more specifically, the downstream face 122, into the gas flowpath 90. Adjusting the angle 128 may further adjust an angle at which the second fuel injection port 123 (
In one embodiment, the inner wall assembly 120 may adjust its depth D into the gas flowpath 90 via pivoting at the point or portion at which the downstream face 122 is coupled to the longitudinal wall 110. For example, the angle 128 at which the downstream face 122 is extended from the longitudinal wall 110 may be adjusted to increase or decrease the depth D at which the upstream face 121 is extended into the gas flowpath 90. In another embodiment, and further in regard to axisymmetric embodiments of the engine 10 generally provided in regard to
In still various embodiments, such as further in regard to supersonic combustion or scramjet embodiments generally described and depicted in regard to
Referring now to
The embodiments of the engine 10 depicted in
Referring now to
Referring now to
For example, in one embodiment, the strut 130 is extended along the height H (
Each strut 130 generally defines a plurality of the region 125 and detonation wave 127 generally fluidly segregated from one another. For example, the combustion section 100 defines a quantity of generally fluidly segregated regions 125 equal to one greater than the quantity of struts 130. Stated alternatively, quantity n struts 130 generates quantity n+1 regions 125. Each of the plurality of regions defines a detonation wave 127 therethrough generally fluidly segregated from one another adjacent regions 125.
Referring still to
In various embodiments, the strut 130 includes a forward wall 131, an aft wall 132, and an axial wall 133. The forward wall 131 and the aft wall 132 are each extended through the depth D of the gas flowpath 90 between the longitudinal walls 110. The axial wall 133 is extended along the lengthwise direction L between the forward wall 131 and the aft wall 132. The forward wall 131 and the aft wall 132 are extended between the longitudinal walls 110 along the depth D of the gas flowpath 90. For example, the forward wall 131 and the aft wall 132 may each extend along the height H (
The forward wall 131 of the strut 130 and the upstream face 121 of the inner wall assembly 120 may together define a groove or cavity at which the detonation region 125 is disposed, such as to define a circuit through which the detonation wave 127 propagates. For example, the forward wall 131 may extend from the longitudinal wall 110 from forward of upstream of the upstream face 121 of the inner wall assembly 120. The aft wall 132 may extend from the longitudinal wall 110 from downstream or aft of the upstream face 121. In one embodiment, the aft wall 132 may extend from approximately where the downstream face 122 of the inner wall assembly 120 and the longitudinal wall 110 are coupled.
Referring now to
Referring now to
The method 1000 includes at 1002 flowing an oxidizer (e.g., oxidizer 81) through a gas flowpath (e.g., gas flowpath 90) into a combustion section (e.g., combustion section 100). At 1004, the method 1000 includes capturing a portion of the flow of oxidizer (e.g., oxidizer 81(a)) via an inner wall (e.g., inner wall assembly 120) extended into a depth of the gas flowpath (e.g., depth D of gas flowpath 90). At 1006, the method 1000 includes flowing a first flow of fuel (e.g., fuel 78) to the portion of the flow of oxidizer (e.g., oxidizer 81(a)) captured via the inner wall. At 1008, the method 1000 includes producing a rotating detonation wave (e.g., detonation wave 127) of detonation gases via a mixture of the first flow of fuel and the portion of oxidizer upstream of the inner wall. At 1010, the method 1000 includes flowing at least a portion of the detonation gases (e.g., detonation gases 126) downstream and mixing the detonation gases with the flow of oxidizer (e.g., oxidizer 81(b)). At 1012, the method 1000 includes flowing a second flow of fuel (e.g., fuel 79) to the mixture of detonation gases and the flow of oxidizer. At 1014, the method 1000 includes burning the mixture of the second flow of fuel, the detonation gases, and the flow of oxidizer to produce combustions gases (e.g., combustion gases 82) to produce thrust.
In various embodiments, the method 1000 further includes at 1016 adjusting a cross sectional area of the gas flowpath based on an operating condition of the engine. In one embodiment, adjusting the cross sectional area of the gas flowpath includes at 1018 adjusting one or more of a pressure, flow, or temperature of the first flow of fuel based at least on an operating condition of the engine. In another embodiment, the operating condition of the engine is based at least on a pressure, temperature, or flow rate of the flow of oxidizer at the combustion section.
In still various embodiments, adjusting the cross sectional area of the gas flowpath includes at 1020 adjusting a depth into the gas flowpath of the inner wall based at least on an operating condition of the engine. In one embodiment, adjusting the depth of the inner wall into the gas flowpath is between approximately 0% and approximately 35% of the depth of the gas flowpath. In another embodiment, adjusting the depth of the inner wall into the gas flowpath is further based at least on a desired minimum number of detonation cells to produce the rotating detonation wave.
In one embodiment, burning the mixture of the second flow of fuel, the detonation gases, and the flow of oxidizer to produce thrust comprises a deflagrative combustion process. In another embodiment, the flow of oxidizer at the combustion section defines a supersonic axial velocity through the gas flowpath producing an oblique shockwave from the flow of oxidizer in the gas flowpath.
In various embodiments, the method 1000 further includes at 1022 adjusting a profile of the oblique shockwave based on an operating condition of the engine. In one embodiment, adjusting the profile of the oblique shockwave includes at 1024 adjusting a depth into the gas flowpath of the inner wall. In another embodiment, adjusting the profile of the oblique shockwave includes at 1026 adjusting a depth into the gas flowpath of the upstream wall (e.g., upstream wall assembly 140).
In still various embodiments, the method 1000 further includes at 1028 adjusting the flow of oxidizer to the inner wall via an upstream wall (e.g., upstream wall assembly 140) disposed upstream of the inner wall. In one embodiment, adjusting the cross sectional area of the gas flowpath further includes at 1030 adjusting a depth into the gas flowpath of the upstream wall based at least on an operating condition of the engine.
The embodiments of the engine 10, combustion section 100, and method 1000 generally shown and described herein may improve combustion stabilization of ramjet and scramjet engines and gas turbine engine inter-turbine or afterburner combustion systems. Various embodiments of the engine 10 and combustion section 100 generally provided herein provide an independent aerodynamic structure and method to produce a cross sectional area change across the gas flowpath 90 via modulation or adjustment of an amount of fuel 78 provided to the detonation combustion region 125 versus an amount of fuel 79 provided for conventional or deflagrative combustion downstream of the detonation region 125. For example, the embodiments generally shown and described herein may enable a gas flowpath 90 cross sectional area change over a plurality of operating conditions of the engine 10 (e.g., different pressure, flow rate, temperature, etc. of the flow of oxidizer 81 into the engine 10). As such, the embodiments generally shown and provided may enable the engine 10 to effectually provide a variable volumetric flow rate of the flow of oxidizer 81 (or, more specifically, flow of oxidizer 81(b)) for conventional combustion (i.e., via fuel 79 downstream of the inner wall assembly 120) different from a volumetric flow rate of the flow of oxidizer 81 entering the engine 10 at the inlet section 20.
Additionally, embodiments of the engine 10 and method 1000 may effectuate a cross sectional area change to produce a variable volumetric flow rate of the flow of oxidizer to the combustion section 100 for mixing and combustion with fuel 79 with generally passive or non-moving structures, such as via modulation of the first flow of fuel 78 to mix with a portion of the flow of oxidizer 81(a) to produce detonation gases 126 at the detonation region 125. For example, the inner wall assembly 120 may define a detonation region 125 to capture a portion of the flow of oxidizer 81(a) and produce detonation gases 126. Modulation of the fuel 78 to produce the detonation gases 126 influences or stabilizes the conventional or deflagrative combustion process further downstream via the second flow of fuel 79, the flow of oxidizer 81(b), and mixed with the detonation gases 126.
Additionally, or alternatively, embodiments of the engine 10 may provide active structures to effectuate changes in a cross sectional area of the gas flowpath 90, such as via the upstream wall assembly 140. In conjunction with the inner wall assembly 120 and modulation of the first flow of fuel 78 to the detonation region, the upstream wall assembly 140 may influence or stabilize the downstream conventional or deflagrative combustion process.
Still further, the inner wall assembly 120, the upstream wall assembly 140, or both may define an oblique shockwave from the flow of oxidizer 81 through the gas flowpath 90. For example, the oblique shockwave may increase a pressure or temperature of the flow of oxidizer 81 toward a center of the gas flowpath 90 (e.g., mid-span of depth D). As such, the oblique shockwave further improves or stabilizes the downstream convention or deflagrative combustion process.
Furthermore, the inner wall assembly 120 providing the first flow of fuel 78 to the detonation region 125 may further improve stabilization of the combustion section 100 at relatively low power operating conditions. For example, a relatively low flow of oxidizer 81 into the engine 10 may be utilized to mix with the fuel 78 and produce detonation gases 126 and thrust at conditions that may generally be too low or unstable for a conventional or deflagrative combustion process via the second flow of fuel 79 mixed with the flow of oxidizer 81(b).
Still furthermore, embodiments of the combustion section 100 generally provided herein may decrease a lengthwise dimension of the engine 10 via improved combustion performance and stability. As such, embodiments of the engine 10, such as ramjet, scramjet, inter-turbine burner, or afterburner/augmentor systems may be improved or integrated into applications heretofore generally limited by known sizes or lengths of such engines or apparatuses to which the engine is installed.
This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they include structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.
Johnson, Arthur Wesley, Pal, Sibtosh, Vise, Steven Clayton, Cooper, Clayton Stuart, Zelina, Joseph
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